A container has an inner cap inside an outer cap and an inner tub inside an outer tub. The outer cap is larger than the inner cap forming a cap cavity with an upper cap cavity and a surrounding cap cavity between the outer cap and the inner cap. Likewise, the outer tub is larger than the inner tub forming a tub cavity with a lower tub cavity and a surrounding tub cavity between the outer tub and the inner tub. The outer cap and the inner cap are on the top side of a cap ledge. The outer tub is connected to the inner tub by a tub ledge. The inner cap has a cap wall, and the outer tub or the inner tub has a tub wall, each threaded to mate and to close the container.

A wine bottle is provided with a punt at a lower end which includes a cork retainer therein. A cork can thus be stored within the cork retainer. In one embodiment, the cork retainer includes two retainer surfaces which are opposing each other horizontally, and spaced apart by a length similar to opposing portions of the cork to allow the cork to fit tightly between these retainer surfaces. Space above the retainer surfaces can hold a foil wrap with the cork within the cork retainer and holding the foil wrap in place. Full re-use of the bottle is thus facilitated. In one embodiment, the bottle has an octagonal shape so that multiple bottles can be shipped together and placed adjacent each other with flat surfaces distributing loads therebetween, without forces concentrated at points thereof, and to keep the bottles in good shape for washing, re-filling and re-use.

This disclosure provides new containers, preforms, methods, and designs for small and light-weight carbonated beverage packaging that provide surprisingly improved carbonation retention and greater shelf life, while still achieving light weight. This disclosure is particularly drawn to small PET containers for carbonated beverages, for example less than or about 400 mL, and methods and designs for their fabrication that attain unexpectedly good carbonation retention and shelf life.

To provide a reinforced glass container which has impact resistance and which can be used for treatment involving exposure to high temperatures or ultraviolet irradiation.

The reinforced glass container of the present invention comprises a glass container and a polymer layer provided on the outer surface of the glass container and having a thickness of more than 1 μm, wherein the polymer layer contains a tetrafluoroethylene type polymer having a melting temperature of more than 260° C. and having carbonyl group-containing groups or hydroxy group-containing groups.

Disclosed herein are glass pharmaceutical vials having sidewalls of reduced thickness. In embodiments, the glass pharmaceutical vial may include a glass body comprising a sidewall enclosing an interior volume. An outer diameter D of the glass body is equal to a diameter d.sub.1 of a glass vial of size X as defined by ISO 8362-1, wherein X is one of 2R, 3R, 4R, 6R, 8R, 10R, 15R, 20R, 25R, 30R, 50R, and 100R as defined by ISO 8362-1. However, the sidewall of the glass pharmaceutical vial comprises an average wall thickness T.sub.i that is less than or equal to 0.85*s.sub.1, wherein s.sub.1 is a wall thickness of the glass vial of size X as defined by ISO 8362-1 and X is one of 2R, 3R, 4R, 6R, 8R, 10R, 15R, 20R, 25R, 30R, 50R, and 100R as defined by ISO 8362-1.

Disclosed herein are glass pharmaceutical vials having sidewalls of reduced thickness. In embodiments, the glass pharmaceutical vial may include a glass body comprising a sidewall enclosing an interior volume. An outer diameter D of the glass body is equal to a diameter d.sub.1 of a glass vial of size X as defined by ISO 8362-1, wherein X is one of 2R, 3R, 4R, 6R, 8R, 10R, 15R, 20R, 25R, 30R, 50R, and 100R as defined by ISO 8362-1. However, the sidewall of the glass pharmaceutical vial comprises an average wall thickness T.sub.i that is less than or equal to 0.85*s.sub.1, wherein s.sub.1 is a wall thickness of the glass vial of size X as defined by ISO 8362-1 and X is one of 2R, 3R, 4R, 6R, 8R, 10R, 15R, 20R, 25R, 30R, 50R, and 100R as defined by ISO 8362-1.

The present disclosure provides a coating composition useful as a coating on food cans, and particularly as interior white or gold food can coatings. The coating composition includes a polyester polymer preferably having a number average molecular weight (Mn) of less than 10,000, a glass transition temperature (Tg) of more than 60° C., and a hydroxyl value greater than 10 mg KOH/g resin. The polyester preferably includes one or more cyclic groups selected from a mono-cyclic group having five ring members or less, a polycyclic group, or both, preferably in a backbone of the polyester polymer.

A metallic bottle can including a metallic base material of the bottle shape that has a mouth portion having a threaded portion, a shoulder portion, a body portion and a bottom portion, wherein, on the outer surface of said mouth portion, a finishing varnish layer is provided directly on said metallic base material, and said finishing varnish layer has an MEK extractability of 2 to 8% by mass.

A light filtering glass container including a glass container coated with a light filtering coating obtained by curing a polymerizable composition including semi-conductive nanoparticles. The absorbance through a 5-micrometer thick light filtering coating is greater than 0.5 for each light wavelength ranging from 350 nm to λ.sub.cut, λ.sub.cut being in the range from 420 nm to 480 nm, and the difference of lightness between the uncoated glass container and the glass container with the light filtering coating is lower than 5.

A container that can be adjusted in height to enable a user to more easily access and/or remove materials in the container after the material content level in the container has dropped below a certain level.